Wearable exoskeleton device for hand rehabilitation

ABSTRACT

An exoskeleton device for assisting the movement of a metacarpal-phalangeal joint of a hand in a flexion/extension plane Γ of the joint, including a metacarpal support arranged integrally with a metacarpal portion of the hand, a phalangeal support having means for fastening to a proximal phalanx, a kinematical chain between the metacarpal support and the phalangeal support arranged to provide and carry out a rotation of the phalangeal support with respect to the metacarpal support.

FIELD OF THE INVENTION

The present invention relates to a wearable mechatronic exoskeleton forneuro-rehabilitation of the limb of a patient, in particular fororthopedic and neurological rehabilitation of the hand. Furtherapplications relate to the use of the exoskeleton for controlling andoperating a remote device (teleoperation) and for studying thebiomechanics of the hand.

A particular aspect of the invention relates to an exoskeleton for theregion of the metacarpal-phalangeal joint of the hand, in particular ofthe thumb and of the index finger.

Another particular aspect of the invention relates to an exoskeleton forthe region of the wrist of the hand.

DESCRIPTION OF THE PRIOR ART

As well known, a problem faced by many mechanical wearable devices(haptic or exoskeleton devices) is to provide a outer kinematic matchingof the device with the anthropometry of the human hand and at the sametime to allow an exchange of physical interactions (forces/couples)without jeopardizing maximum safety for the human user.

In case of assistance and rehabilitation, the need is felt of astructure capable of bearing and detecting external loads andtransmitting them in a comfortable and safe way to the human joints. Oneof the risks is a to introduce too many constraints to the mechanicalstructure of the device.

In fact, an exoskeleton structure that is strong enough is also verystiff when coupled with the human kinematic structure, and then cannotoperate with efficiency, owing to many effects, such as the misalignmentof the axes of the robotic joints with the human joints and thevariability of the conformation external of the human body, jeopardizingthe operation of the device.

The particular case of the hand has such problems in a very extendedway, owing to its wide mobility and the small size of its segments. Forthis reason, the research for solutions to this problem is verydesirable in rehabilitation, where therapies mediated by roboticapparatus are the most used for their large potentiality; in particular,mechanical wearable devices are desirable that allow the assistance tothe only anatomical joints of the fingers of the patient, withoutimpeding natural movements and without causing excessive discomfort.

A very high interest is concentrated on the functional rehabilitation ofthe grip of the hand, such as a cylindrical grip and precision grip. Forthis reason it is necessary that the exoskeleton device does not impedethe palm of the hand and bending the wrist of the patient for keepingthe position of the hand with respect to arm during the gripanatomically correct.

An exoskeleton device for the arm that comprises an exoskeleton for thehand is described in WO2009016478A2, which allows assisting the movementof the metacarpal-phalangeal joint and of the interphalangeal joints ofthe hand.

Such reference provides the alignment of the axes of the phalanxes ofthe exoskeleton joints with the axes of the interphalangeal joints, inorder to reduce constraint forces on the joints and to improve kinematiccompatibility between the movement of the fingers and those of theexoskeleton.

Concerning the metacarpal-phalangeal joint, a backing member which canbe fixed out of the metacarpus and a shell element which can be fixed tothe proximal phalanx are provided, pivotally connected to each other bya metacarpal-phalangeal exoskeleton joint. Such solution, however, doesnot allow to this exoskeleton joint the alignment with themetacarpal-phalangeal joint, and therefore, for this joint, there is notthe same kinematic compatibility that there is for the interphalangealjoints, causing the presence of constraint forces that reduce remarkablythe comfort of use.

Furthermore, the exoskeleton cited is not completely implemented in caseof different anthropometric hand sizes, causing a possible increase ofthe constraint forces on the metacarpal-phalangeal joints.

Another drawback high of the device above cited, relates to a lowadaptation of the exoskeleton joint to the actual flexion/extensionrotation axis of the metacarpal-phalangeal joint, that, as well known,is unsteady during this rotation movement.

Another exoskeleton for the hand of known type is disclosed inEP2436358. In this case a support for fastening the exoskeleton to theback of the hand of the user and five mechanical fingers connected tothe support are provided. Each mechanical finger comprises a stiffproximal element integral to the support and an intermediate stiffelement mechanically connected to the stiff proximal element. More indetail, the intermediate stiff element can rotate in a forced way withrespect to the stiff proximal element. In fact the intermediate stiffelement comprises an arm having an end forced to move in an arc-shapedrail guide made in the stiff proximal element. An adjustable connectionis also provided whose length varies responsive to the movement of theintermediate stiff element with respect to the stiff proximal element.

Since the centre of rotation the arc-shaped rail guide is locatedapproximately at the centre of rotation of the anatomicalmetacarpal-phalangeal joint, said exoskeleton causes a lower presence ofconstraint forces on the anatomical joint than the WO2009016478A2exoskeleton.

However, also in this case an actual elimination of the constraintforces on the metacarpal joint is substantially impossible. This is dueboth to the fact that the stiff proximal element is integral to thefastening support to the back of the hand and to the fact that theradius of the arc-shaped rail guide cannot be altered. Therefore, theexoskeleton described in EP2436358 does not allow adaptation to thestructure to various anthropometric hand sizes, nor it can follow thecentre of rotation of the metacarpal-phalangeal joint that, as said,changes position during the use.

Therefore also the exoskeleton described in EP2436358 is not verycomfortable for a user and it can be also detrimental for the joints ofthe fingers of the hand, owing to the generation of the above describedconstraint forces.

SUMMARY OF THE INVENTION

It is therefore a feature of the present invention to provide a devicefor overcoming the above described drawbacks of the exoskeleton devicesof the prior art, and, in particular for assisting the flexion/extensionof the joints of a hand by means of a pure torque that does not generateconstraint forces on the metacarpal-phalangeal and interphalangealjoints, moving them for their whole natural workspace.

It is also a feature of the present invention to provide such a devicethat can be adapted to different anthropometric hand sizes.

It is a further feature of the present invention to provide such adevice that is compatible with the three-dimensional configuration ofthe carpal-metacarpal joint of the thumb finger of the hand, i.e. thatallows the free movement of opposition and of ab/adduction of the thumb.

It is another feature of the present invention to provide such a devicethat allows the free movements of flexion/extension and of ab/adductionto the metacarpal-phalangeal joints of the fingers of the hand.

It is also a feature of the present invention to provide such a devicethat is adaptable to an unsteady anatomical axis during theflexion/extension movement of the metacarpal-phalangeal joint.

It is also a feature of the present invention to provide such a devicethat presents a minimum encumbrance and a weight less than the priorart.

It is still a feature of the present invention to provide such a devicethat provides assistance to the flexion/extension of the anatomicaljoint of the wrist and that ensures also free ab/adduction movements.

These and other objects are achieved by an exoskeleton device forassisting the movement of a metacarpal-phalangeal joint of a hand in aflexion/extension plane Γ of the joint, the metacarpal-phalangeal jointarranged for carrying out a rotation θ about an axis z substantiallyorthogonal to the flexion/extension plane;

-   -   comprising:        -   a metacarpal support arranged to be kept integral to a            metacarpal portion of the hand;        -   a phalangeal support having means for fastening to a            proximal phalanx;        -   a kinematical chain between the metacarpal support and the            phalangeal support to provide and carrying out a rotation of            the phalangeal support with respect to the metacarpal            support;    -   said kinematical chain between the metacarpal support and the        phalangeal support comprising:        -   a metacarpal slide arranged to translate with respect to the            metacarpal support along a predetermined line γ arranged in            the flexion/extension plane Γ;        -   a stiff link pivotally connected to the metacarpal slide by            a first pivotal constraint;        -   a second pivotal constraint arranged to connect pivotally            the stiff link to the phalangeal support;        -   an actuating means for causing a first rotation to the stiff            link at the first pivotal constraint and a second rotation            to the phalangeal support at the second pivotal constraint.

In particular, the actuating means is configured for zeroing theconstraint forces of the exoskeleton device on the metacarpal-phalangealjoint versus the rotation θ, for any position of themetacarpal-phalangeal joint with respect to the exoskeleton devicewithin a predetermined range.

This way, instead of seeking a coincidence between themetacarpal-phalangeal joint axis and the axis of the exoskeleton,according to the invention, a kinematical chain between the metacarpalsupport and the phalangeal support is made in such a way that at therelative position between the metacarpal-phalangeal joint and theexoskeleton device, within a predetermined range, the constraint forcesof the exoskeleton device on the metacarpal-phalangeal joint are zeroversus the rotation θ of the anatomic metacarpal-phalangeal joint.

In particular, the exoskeleton device, according to the invention,allows that two stiff links are actuated without generating constraintforces on the metacarpal-phalangeal joint, whichever is the instantposition of the axis z about which the metacarpal-phalangeal jointrotates. Such aspect is particularly advantageous with respect to theexoskeletons of the prior art, since it allows the exoskeleton of thepresent invention to adapt to the different positions that the rotationaxis z assumes during the rotation of the metacarpal-phalangeal joint.Furthermore, the exoskeleton, according to the present invention, canadapt automatically to different anthropometric sizes, ensuring that themetacarpal-phalangeal joint is not subject to undetermined constraintforces.

Preferably, the second pivotal constraint is the only element providedbetween the stiff link and the phalangeal support.

Advantageously, the first rotation and the second rotation of the firstand the second pivotal constraints are made by means of respectivepulleys arranged at the first and the second pivotal constraints and byat least one cable that causes the pulleys to rotate. This way, therotation of the phalangeal support can be remotely actuated, for exampleby means of Bowden cables.

In particular, the actuating means remotely comprises a rotor arrangedto cause the first rotation to the first pivotal constraint and at leastone cable arranged to connect the first and the second pivotalconstraints, such that the first and the second rotation are synchronousto each other. In this case, the first pivotal constraint, in particularthe first pulley, is idle and the second pivotal constraint is integralto the phalangeal support, in order to transmit the rotation of thephalangeal support about the second pivotal constraint.

In particular, the pulleys have a same radius, in such a way that notonly the constraint forces caused by the operation of the rotation ofthe phalangeal support are zeroed, but also possible constraint forcescaused by the beats of the Bowden cable, in particular constraintmoments at the pulleys, are not generated.

In a possible embodiment the device is configured for assisting themetacarpal-phalangeal joint of the index finger of the hand, andcomprises a kinematical ab/adduction chain of the index finger locatedbetween the metacarpal support and the slide, the kinematicalab/adduction chain of the index finger being configured for assistingthe movement of the metacarpal-phalangeal joint in an ab/adduction planeof the metacarpal-phalangeal joint substantially orthogonal to theflexion/extension plane Γ, in such a way that the exoskeleton device canalways lay in the flexion/extension plane Γ.

In particular, the kinematical ab/adduction chain of the index fingercomprises:

-   -   an ab/adduction slide arranged to translate with respect to the        metacarpal support along a predetermined line ε arranged in the        ab/adduction plane;    -   an ab/adduction pivotal constraint by which the metacarpal slide        of the exoskeleton device is pivotally connected to the slide of        the kinematical chain.

This way, owing to the co-presence of the slide more complete movementsof ab/adduction can be carried out, i.e. similar to the real ones, suchas the conical rotation of the index finger obtained by a combination ofthe flexion/extension and of the ab/adduction of the index finger same.

In another possible embodiment the device is configured for assistingthe metacarpal-phalangeal joint of the thumb finger of the hand,comprising a kinematical chain of the thumb located between themetacarpal support and the stiff link. In particular, the kinematicalchain of the thumb is configured for assisting the flexion/extension andab/adduction movements of a carpal-metacarpal joint of the thumb. Suchkinematical chain of the thumb comprises:

-   -   a first shaft arranged to rotate about its own axis with respect        to the metacarpal support, by a pivotal connection;    -   a first segment pivotally connected to the shaft by a first        pivotal constraint;    -   a second segment pivotally connected to the first segment by a        second pivotal constraint;    -   a second shaft arranged to rotate about its own axis with        respect to the second segment, by a pivotal connection;    -   a slide pivotally connected to the second shaft by a pivotal        constraint, the slide arranged to translate with respect to the        pivotal constraint along a predetermined line λ and being also        connected to the stiff link.

This way, the exoskeleton is compatible with the three-dimensionalconfiguration of the carpal-metacarpal joint of the thumb finger of thehand, allowing the free movement of opposition and of ab/adduction ofthe thumb.

In a possible embodiment a serial mechanism for the wrist is furtherprovided, operatively connected to the metacarpal support, arranged toassist the flexion/extension of the anatomical joint of the wrist,ensuring also free ab/adduction movements.

Such serial mechanism for the wrist may comprise:

-   -   an ulnar support arranged to be kept integral to a distal        portion of the forearm;    -   an ulnar slide adapted to translate with respect to said ulnar        support along a predetermined line δ substantially parallel to        the longitudinal direction of the forearm;    -   an articulated quadrilateral comprising:        -   a first connecting rod and a second connecting rod, parallel            to each other and arranged in a direction substantially            parallel to the line δ; a first segment pivotally connected            to the slide by a pivotal constraint;        -   a second segment rigidly connected to the metacarpal            support.

In particular, the first and second segments can be arranged to connectbetween them the ends of the connecting rods by means of four passivespherical joints, in such a way that the metacarpal support can rotatewith respect to the ulnar support about an axis whose position is notdetermined, adapting passively to the rotation of the anatomical jointof the wrist, according to the two axes that are perpendicular to thelongitudinal direction of the forearm, without causing residualconstraint forces.

Advantageously, a second serial mechanism is provided that isoperatively connected to the metacarpal support and is arranged toreinforce the coupling between the ulnar support and the metacarpalsupport.

Such second serial mechanism may comprise:

-   -   a rotatable slide arranged to translate with respect to the        ulnar support along a predetermined line σ and to rotate about        the line σ with respect to the ulnar support, said line σ being        substantially perpendicular to the line δ;    -   a further slide arranged to translate with respect to the        rotatable slide along a predetermined line ρ substantially        perpendicular to the line σ, said slide being connected to the        metacarpal support by a ball joint.

Preferably, the exoskeleton device is configured for assisting themovement of a metacarpal-phalangeal joint of the index finger and of thethumb, as well as of the wrist of a hand as above defined.

According to another aspect of the invention, an exoskeleton device forassisting the movement of a metacarpal-phalangeal joint and of the wristof a hand, said metacarpal-phalangeal joint arranged for carrying out arotation θ about an axis z substantially orthogonal to aflexion/extension plane Γ of the joint, comprises:

-   -   a metacarpal support arranged to be kept integral to a        metacarpal portion of the hand;    -   a phalangeal support having means for fastening to a proximal        phalanx;    -   a kinematical chain between the metacarpal support and the        phalangeal support to provide and carrying out a rotation of the        phalangeal support with respect to the metacarpal support;    -   a serial mechanism for the wrist operatively connected to the        metacarpal support and arranged to assist the flexion/extension        of the anatomical joint of the wrist, ensuring also free        ab/adduction movements, said serial mechanism for the wrist        comprising an ulnar support arranged to be kept integral to a        distal portion of the forearm;

In particular, the serial mechanism for the wrist comprises furthermore:

-   -   an ulnar slide adapted to translate with respect to the ulnar        support along a predetermined line δ substantially parallel to        the longitudinal direction of the forearm;    -   an articulated quadrilateral comprising:        -   a first connecting rod and a second connecting rod, parallel            to each other and arranged in a direction substantially            parallel to the line δ;        -   a first segment pivotally connected to the slide by a            pivotal constraint;        -   a second segment rigidly connected to the metacarpal            support;    -   said first and the second segment arranged to connect between        them the ends of the connecting rods by means of four passive        spherical joints;    -   in such a way that the metacarpal support can rotate with        respect to the ulnar support about an axis whose position is not        determined, the articulated quadrilateral being adaptable        passively to the rotation of the anatomical joint of the wrist,        according to both the axes that are perpendicular to the        longitudinal direction of the forearm, without causing residual        constraint forces.

In this case, a second serial mechanism can be also provided that isoperatively connected to the metacarpal support and is arranged toreinforce the coupling between the ulnar support and the metacarpalsupport, the second serial mechanism comprising:

-   -   a rotatable slide arranged to translate with respect to the        ulnar support along a predetermined line σ and to rotate with        respect to the ulnar support about the line σ, said line σ being        substantially perpendicular to the line δ;    -   a slide arranged to translate with respect to the rotatable        slide along a predetermined line ρ substantially perpendicular        to the line σ, said slide being connected to the metacarpal        support by a ball joint.

BRIEF DESCRIPTION OF THE DRAWINGS

Further characteristic and/or advantages of the wearable exoskeletondevice for rehabilitation of the hand, according to the presentinvention will be made clearer with the following description of anexemplary embodiment thereof, exemplifying but not limitative, withreference to the attached drawings in which:

FIG. 1 shows a diagrammatical view of the exoskeleton device, accordingto the invention, for assisting the movement of a metacarpal-phalangealjoint of a hand in a flexion/extension plane of the joint same;

FIG. 2 shows a diagram of an exoskeleton device, according to theinvention, mounted to the index finger of a hand;

FIG. 3 shows a possible exemplary embodiment of the exoskeleton deviceof FIG. 2 applied to the index finger of the hand;

FIGS. 4A and 4B show the exoskeleton device, mounted to the index fingerof a hand, respectively in its extended and flexed configurations;

FIG. 5 shows a possible exemplary embodiment of the exoskeleton deviceof FIG. 2;

FIG. 6 shows a pattern that is diagrammatically shown in an exemplaryembodiment of the exoskeleton device according to the invention mountedto the thumb finger of the hand;

FIG. 7 shows a possible exemplary embodiment of the exoskeleton deviceof FIG. 6 applied to the thumb finger of the hand;

FIG. 8 shows a possible exemplary embodiment of the exoskeleton deviceshown in FIG. 6;

FIG. 9 shows a possible exemplary embodiment of the exoskeleton devicemounted both to the index finger and to the thumb finger of the hand;

FIG. 10 shows a conceptual diagram of a serial mechanism, operativelyconnected to the exoskeleton device, arranged to assist the rotation ofthe anatomical joint of the wrist;

FIG. 11 shows a possible exemplary embodiment of the serial mechanismshown in FIG. 9;

FIG. 12 shows an exemplary embodiment of the serial mechanism of FIG.10.

DESCRIPTION OF A PREFERRED EXEMPLARY EMBODIMENT

In FIG. 1A a diagrammatical view is shown of an exoskeleton device 100,according to the invention, for assisting the movement of ametacarpal-phalangeal joint 50, i.e. between the metacarpal bone andproximal phalanx of the finger of a hand in a flexion/extension plane ofthe joint same. The exoskeleton device 100 comprises:

-   -   a metacarpal support 150 arranged to be kept integral to a        metacarpal portion of the hand;    -   a slide 101 arranged to provide an axial sliding movement along        a predetermined line γ with respect to the metacarpal support        150;    -   a stiff link 103 pivotally connected to the slide 101 by a first        pivotal constraint 102;    -   a phalangeal support 105 pivotally connected to the stiff link        103 by a second pivotal constraint 104;    -   an actuating means for causing a first rotation to the stiff        link 103 and a second rotation to the phalangeal support 105        respectively at the first 102 and second 104 pivotal constraint.

The presence of the slide 101 provides a sufficient lability to thesystem, and the two rotational couplings 102 and 104, even if none ofthem is coincident with the anatomical axis of the metacarpal-phalangealjoint, determine a minimum and in particular zero, constraint forcesthat are transmitted to the joint.

Indicating as Γ the plane of flexion/extension containing the slidingaxial, the flexion/extension movement that the metacarpal-phalangealjoint 50 can carry out consists of a rotation θ about an axis z that issubstantially orthogonal to the flexion/extension plane Γ.

Defining then a point O as the intersection between the rotation axis zof the joint 50 and plane Γ, and a point O′ as the origin of the axialsliding movement of the slide, the relative coordinates between O and O′are H and V, respectively in a direction parallel and in a directionwhich is orthogonal to the line γ.

A diagrammatical view of the forces in play is shown in FIG. 1B. Fromthe figure the following relations can be determined:

$\left\{ {\begin{matrix}{Y_{R} = Y_{1}} \\{X_{R} = {X_{1} = 0}} \\{M_{R} = M_{1}}\end{matrix}\left\{ {\begin{matrix}{Y_{2} = Y_{1}} \\{X_{2} = 0} \\{{M_{1} + {Y_{1}l_{1}}} = T_{1}}\end{matrix}\left\{ {\begin{matrix}{Y_{3} = Y_{2}} \\{X_{3} = {X_{2} = 0}} \\{{T_{1} + {Y_{2}l_{2}^{\prime}}} = T_{2}}\end{matrix}\left\{ \begin{matrix}{R_{2} = Y_{3}} \\{R_{1} = {{- X_{3}} = 0}} \\{{T + T_{2}} = {R_{2}l_{2}^{~\prime}}}\end{matrix} \right.} \right.} \right.} \right.$

Starting from the previous equations, the torques T₁ and T₂ caused bythe actuating means to the first pivotal constraint 102 and to thesecond pivotal constraint 104 are equal, then the constraint forcespresent on the constraint anatomical 50 are zero, versus the rotation θ,within a predetermined range of H and V.

In FIG. 2 the conceptual pattern is shown of an exoskeleton device 100,according to the invention, mounted to the index finger of a hand. Forthe sake of clarity, the anatomical parts have been hatched.

In FIG. 3 a possible exemplary embodiment is shown of the exoskeletondevice 100 applied to the index finger of the hand. In this exemplaryembodiment, the rotational constraints 102 and 104 are made by means ofidle pulleys and the actuating means consists of Bowden cables 120 whoseinner wires are wound about such pulleys 102 and 104.

In the FIGS. 4A and 4B the exoskeleton device 100 is shown, mounted tothe index finger of a hand, respectively in its extended and flexedconfigurations. With the dashed line the chain of the exoskeleton jointsis indicated, whereas with the dash-dot line the chain of the anatomicjoints is indicated.

In FIG. 5 a possible exemplary embodiment is shown of the exoskeletondevice 100 shown in FIG. 2, in which between the metacarpal support 150and the slide 101 a kinematical chain 200 is located for the exoskeletondevice 100 to follow passively the movement of ab/adduction of themetacarpal-phalangeal joint 50. Such kinematical chain 200 comprises:

-   -   a slide 201 arranged to provide an axial sliding movement with        respect to the metacarpal support 150 along a predetermined line        ε arranged in the ab/adduction plane of the        metacarpal-phalangeal joint;    -   a pivotal constraint 202 by which the slide 101 of the        exoskeleton device 100 is pivotally connected to the slide 201        of the kinematical chain 200.

In FIG. 6 a diagram is shown of the exoskeleton device 100 mounted tothe thumb finger of the hand. The hatched parts, corresponding to theanatomical parts of the joint, comprise the metacarpal-phalangeal joint50 and the carpal-metacarpal joint 40.

In FIG. 7 a possible exemplary embodiment is shown of the exoskeletondevice 100 applied to the thumb finger of the hand. In this exemplaryembodiment, the rotational constraints 102 and 104 are made by means ofidle pulleys and the actuating means consists of Bowden cables 120 whoseinner wires are wound about such pulleys 102 and 104.

In FIG. 8 a possible exemplary embodiment is shown of the exoskeletondevice 100 shown in FIG. 6, in which between the metacarpal support 150and the stiff link 103 a kinematical chain 400 is located for theexoskeleton device (100) for assisting the flexion/extension andab/adduction movements of the carpal-metacarpal joint 40 of the thumb.Such kinematical chain 400 comprises:

-   -   a first shaft 459 arranged to rotate about its own axis with        respect to the metacarpal support 150, by a pivotal connection        460;    -   a first segment 453 pivotally connected to shaft 459 by a first        pivotal constraint 452;    -   a second segment 455 pivotally connected to the first segment        453 by a second pivotal constraint 454;    -   a second shaft 457 arranged to rotate about its own axis with        respect to the second segment 455, by pivotal connection 456;    -   a slide 451 pivotally connected to the second shaft 457 by a        pivotal constraint 458.

The slide 451 is arranged to slide along a predetermined line λ withrespect to the pivotal constraint 458 and is also connected to the stifflink 103.

Rotational constraints 452 and 454 and the rotational coupling 456 and460 are actuated and are not passive with respect to the movement of thejoint 40.

In particular, the operation of the pivotal connection 460 can assistmainly the movement of ab/adduction of the carpal-metacarpal joint 40,whereas the operation of rotational constraints 452 and 454 and ofpivotal connection 456 can assist mainly the flexion/extension movementof the carpal-metacarpal joint 40.

In FIG. 9 a possible exemplary embodiment is shown of the exoskeletondevice applied both to the index finger and to the thumb finger of thehand. For graphical clarity, the numbers of the elements of the device100 mounted to the index finger are indicated with a prime, whereas thenumbers of the elements of the device 100 mounted to the thumb fingerare indicated with two primes.

In FIG. 10 a conceptual pattern is shown of a serial mechanism 300,operatively connected to the metacarpal support 150 of the exoskeletondevice 100, arranged to assist the flexion/extension of the anatomicaljoint of the wrist 30, ensuring also free ab/adduction movements. Theserial mechanism 300 comprises:

-   -   an ulnar support 302 arranged to be kept integral to a distal        portion of the forearm 20;    -   a slide 301 arranged to slide with respect to the ulnar support        302 along a predetermined line 5 substantially parallel to the        longitudinal direction of the forearm;    -   an articulated quadrilateral 303 comprising:        -   a first connecting rod 303 a and a second connecting rod 303            b, parallel to each other and arranged in a direction            substantially parallel to the line δ;        -   a first segment 303 c pivotally connected to the slide 301            by a pivotal constraint 304;        -   a second segment 303 d rigidly connected to the metacarpal            support 150.

The first segment 303 c and the second segment 303 d are adapted toconnect between them the ends of the connecting rods 303 a and 303 b bymeans of four passive spherical joints, in such a way that themetacarpal support 150 can rotate with respect to the ulnar support 302about an axis whose position is not determined. In particular, thearticulated quadrilateral 303 can adapt passively to the rotation of theanatomical joint of the wrist, according to both the axes that areperpendicular to the longitudinal direction of the forearm, withoutcausing residual constraint forces. The assistance of theflexion/extension movement of the anatomical joint is made by theoperation of the pivotal constraint 304.

In FIG. 11 a possible exemplary embodiment is shown of the serialmechanism 300 shown in FIG. 9, where a second serial mechanism (350) isfurther provided, completely passive and operatively connected to themetacarpal support 150, arranged to constrain in a compliant way thematching between the ulnar support 302 and the metacarpal support 150,the second serial mechanism (350) comprising:

-   -   a rotatable slide 351 arranged to slide with respect to the        ulnar support 302 along a predetermined line σ and arranged to        rotate about the line σ with respect to a same ulnar support        302, said line σ being substantially perpendicular to the line        δ;    -   a slide 352 arranged to rotate with respect to the rotatable        slide 351 along a predetermined line ρ substantially        perpendicular to line σ.

The slide 352 is also connected to the metacarpal support 150 by a balljoint.

In FIG. 12 an exemplary embodiment is shown of the serial mechanism 300of FIG. 10.

The foregoing description of specific exemplary embodiments will sofully reveal the invention according to the conceptual point of view, sothat others, by applying current knowledge, will be able to modifyand/or adapt in various applications the specific exemplary embodimentswithout further research and without parting from the invention, and,accordingly, it is meant that such adaptations and modifications willhave to be considered as equivalent to the specific embodiments. Themeans and the materials to realize the different functions describedherein could have a different nature without, for this reason, departingfrom the field of the invention. It is to be understood that thephraseology or terminology that is employed herein is for the purpose ofdescription and not of limitation.

The work of search that has brought to this invention has received afinancing by the Seventh Frame Program of the European UnionFP7/2007-2013, in the field of the Project WAY, financing agreement n.288551.

1. An exoskeleton device (100) for assisting the movement of ametacarpal-phalangeal joint (50) of a hand in a flexion/extension planeΓ of said joint, said metacarpal-phalangeal joint (50) arranged forcarrying out a rotation θ about an axis z substantially orthogonal tosaid flexion/extension plane, comprising: a metacarpal support (150)arranged to be kept integral to a metacarpal portion of the hand; aphalangeal support (105) having means for fastening to a proximalphalanx; a kinematical chain between said metacarpal support (150) andsaid phalangeal support (105) to provide and carrying out a rotation ofsaid phalangeal support (105) with respect to said metacarpal support(150); characterized in that said kinematical chain comprises: ametacarpal slide (101) arranged to slide with respect to said metacarpalsupport (150) along a predetermined line γ, said predetermined line γarranged in said flexion/extension plane Γ; a stiff link (103) pivotallyconnected to said metacarpal slide (101) by a first pivotal constraint(102); a second pivotal constraint (104) arranged to connect pivotallysaid stiff link (103) to said phalangeal support (105); an actuatingmeans for causing a first rotation to said stiff link (103) at saidfirst pivotal constraint (102), and for causing a second rotation tosaid phalangeal support (105) at said second pivotal constraint (104),said actuating means being configured for zeroing the constraint forcesof said exoskeleton device on said metacarpal-phalangeal joint (50)versus said rotation θ, for any position of said metacarpal-phalangealjoint (50) with respect to said exoskeleton device, within apredetermined range.
 2. The exoskeleton device (100), according to claim1, wherein said first rotation and said second rotation of said firstand said second pivotal constraints are made by means of respectivepulleys arranged at said first and said second pivotal constraints andby at least one cable that causes said pulleys to rotate, in particularsaid pulleys having a same radius.
 3. The exoskeleton device (100),according to claim 1, configured for assisting the metacarpal-phalangealjoint (50) of the index finger of said hand, comprising a kinematicalchain (200) located between said metacarpal support (150) and said slide(101), said kinematical chain (200) being configured for assisting themovement of said metacarpal-phalangeal joint (50) in an ab/adductionplane of said metacarpal-phalangeal joint (50) substantially orthogonalto said flexion/extension plane Γ, in such a way that said exoskeletondevice (100) can always lay on said flexion/extension plane Γ, Inparticular, said kinematical chain (200) comprises: an ab/adductionslide (201) arranged to slide with respect to said metacarpal support(150) along a predetermined line ε, said predetermined line ε arrangedin said ab/adduction plane; an ab/adduction pivotal constraint (202) bywhich said metacarpal slide (101) of said exoskeleton device (100) ispivotally connected to said slide (201) of said kinematical chain (200).4. The exoskeleton device (100), according to claim 1, configured forassisting the metacarpal-phalangeal joint (50) of the thumb finger ofsaid hand, comprising a kinematical chain (400) located between saidmetacarpal support (150) and said stiff link (103), said kinematicalchain (400) being configured for assisting the flexion/extension andab/adduction movements of a carpal-metacarpal joint (40) of said thumb,in particular said kinematical chain (400) comprising: a first shaft(459) arranged to rotate about its own axis with respect to saidmetacarpal support (150), by a pivotal connection (460); a first segment(453) pivotally connected to said shaft (459) by a first pivotalconstraint (452); a second segment (455) pivotally connected to saidfirst segment (453) by a second pivotal constraint (454); a second shaft(457) arranged to rotate about its own axis with respect to said secondsegment (455), by a pivotal connection (456); a slide (451) pivotallyconnected to said second shaft (457) by a pivotal constraint (458), saidslide (451) arranged to slide with respect to said pivotal constraint(458) along a predetermined line λ and being also connected to saidstiff link (103).
 5. The exoskeleton device (100), according to claim 2,wherein said actuating means comprises a rotor arranged to cause saidfirst rotation to said first pivotal constraint (102) and at least onecable arranged to connect said first (102) and said second pivotalconstraint (104), such that said first and said second rotation aresynchronous to each other.
 6. The exoskeleton device (100), according toclaim 1, wherein a serial mechanism for the wrist is further provided(300) operatively connected to said metacarpal support (150) andarranged to assist the flexion/extension of the anatomical joint of thewrist (30), ensuring also free ab/adduction movements, said serialmechanism for the wrist (300) comprising: an ulnar support (302)arranged to be kept integral to a distal portion of the forearm (20); anulnar slide (301) arranged to slide with respect to said ulnar support(302) along a predetermined line δ, said line δ being substantiallyparallel to the longitudinal direction of said forearm; an articulatedquadrilateral (303) comprising: a first connecting rod (303 a) and asecond connecting rod (303 b), parallel to each other and arranged in adirection substantially parallel to said line δ; a first segment (303 c)pivotally connected to said slide (301) by a pivotal constraint (304); asecond segment (303 d) rigidly connected to said metacarpal support(150); said first (303 c) and said second (303 d) segment arranged toconnect between them the end of said connecting rods (303 a, 303 b) bymeans of four passive spherical joints; in such a way that saidmetacarpal support (150) can rotate with respect to said ulnar support(302) about an axis whose position is not determined, said articulatedquadrilateral (303) being adaptable passively to the rotation of theanatomical joint of the wrist, according to both axes that areperpendicular to the longitudinal direction of the forearm, withoutcausing residual constraint forces.
 7. The exoskeleton device forassisting the movement of the joints of a hand, according to claim 6,wherein a second serial mechanism (350) is provided, operativelyconnected to said metacarpal support (150) and is arranged to reinforcethe coupling between said ulnar support (302) and said metacarpalsupport (150), said second serial mechanism (350) comprising: arotatable slide (351) arranged to slide with respect to said ulnarsupport (302) along a predetermined line σ and arranged to rotate aboutsaid line σ with respect to said ulnar support (302), said line σ beingsubstantially perpendicular to said line δ; a slide (352) arranged totranslate with respect to said rotatable slide (351) along apredetermined line ρ, said line ρ being substantially perpendicular tosaid line σ, said slide (352) being connected to said metacarpal support(150) by a ball joint.
 8. The exoskeleton device (100) for assisting themovement of a metacarpal-phalangeal joint (50) and of the wrist (30) ofa hand according to claim
 3. 9. An exoskeleton device (100) forassisting the movement of a metacarpal-phalangeal joint (50) and of thewrist (30) of a hand, said metacarpal-phalangeal joint (50) arranged forcarrying out a rotation θ about an axis substantially orthogonal to aflexion/extension plane Γ of said joint, said device (100) comprising: ametacarpal support (150) arranged to be kept integral to a metacarpalportion of the hand; a phalangeal support (105) having means forfastening to a proximal phalanx; a kinematical chain between saidmetacarpal support (150) and said phalangeal support (105) to provideand carrying out a rotation of said phalangeal support (105) withrespect to said metacarpal support (150); a serial mechanism for thewrist (300) operatively connected to said metacarpal support (150) andarranged to assist the flexion/extension of the anatomical joint of thewrist (30), ensuring also free ab/adduction movements, said serialmechanism for the wrist (300) comprising an ulnar support (302) arrangedto be kept integral to a distal portion of the forearm (20); said device(100) characterized in that said serial mechanism for the wrist (300)comprises furthermore: an ulnar slide (301) arranged to slide withrespect to said ulnar support (302) along a predetermined line δ, saidline δ being substantially parallel to the longitudinal direction ofsaid forearm; an articulated quadrilateral (303) comprising: a firstconnecting rod (303 a) and a second connecting rod (303 b), parallel toeach other and arranged in a direction substantially parallel to saidline δ; a first segment (303 c) pivotally connected to said slide (301)by a pivotal constraint (304); a second segment (303 d) rigidlyconnected to said metacarpal support (150); said first (303 c) and saidsecond (303 d) segment arranged to connect between them the end of saidconnecting rods (303 a, 303 b) by means of four passive sphericaljoints; in such a way that said metacarpal support (150) can rotate withrespect to said ulnar support (302) about an axis whose position is notdetermined, said articulated quadrilateral (303) being adaptablepassively to the rotation of the anatomical joint of the wrist,according to both the axes that are perpendicular to the longitudinaldirection of the forearm, without causing residual constraint forces.10. The exoskeleton device for assisting the movement of the joints of ahand, according to claim 9, wherein a second serial mechanism (350) isprovided, operatively connected to said metacarpal support (150) and isarranged to reinforce the coupling between said ulnar support (302) andsaid metacarpal support (150), said second serial mechanism (350)comprising: a rotatable slide (351) arranged to slide with respect tosaid ulnar support (302) along a predetermined line σ and arranged torotate about a line σ with respect to said ulnar support (302), saidline σ being substantially perpendicular to said line δ; a slide (352)arranged to slide with respect to said rotatable slide (351) along apredetermined line ρ, said line ρ being substantially perpendicular tosaid line σ, said slide (352) being connected to said metacarpal support(150) by a ball joint.